TY - JOUR
T1 - Proteome constraints reveal targets for improving microbial fitness in nutrient-rich environments
AU - Chen, Yu
AU - van Pelt-KleinJan, Eunice
AU - van Olst, Berdien
AU - Douwenga, Sieze
AU - Boeren, Sjef
AU - Bachmann, Herwig
AU - Molenaar, Douwe
AU - Nielsen, Jens
AU - Teusink, Bas
PY - 2021
Y1 - 2021
N2 - Cells adapt to different conditions via gene expression that tunes metabolism for maximal fitness. Constraints on cellular proteome may limit such expression strategies and introduce trade-offs. Resource allocation under proteome constraints has explained regulatory strategies in bacteria. It is unclear, however, to what extent these constraints can predict evolutionary changes, especially for microorganisms that evolved under nutrient-rich conditions, i.e., multiple available nitrogen sources, such as Lactococcus lactis. Here, we present a proteome-constrained genome-scale metabolic model of L. lactis (pcLactis) to interpret growth on multiple nutrients. Through integration of proteomics and flux data, in glucose-limited chemostats, the model predicted glucose and arginine uptake as dominant constraints at low growth rates. Indeed, glucose and arginine catabolism were found upregulated in evolved mutants. At high growth rates, pcLactis correctly predicted the observed shutdown of arginine catabolism because limited proteome availability favored lactate for ATP production. Thus, our model-based analysis is able to identify and explain the proteome constraints that limit growth rate in nutrient-rich environments and thus form targets of fitness improvement.
AB - Cells adapt to different conditions via gene expression that tunes metabolism for maximal fitness. Constraints on cellular proteome may limit such expression strategies and introduce trade-offs. Resource allocation under proteome constraints has explained regulatory strategies in bacteria. It is unclear, however, to what extent these constraints can predict evolutionary changes, especially for microorganisms that evolved under nutrient-rich conditions, i.e., multiple available nitrogen sources, such as Lactococcus lactis. Here, we present a proteome-constrained genome-scale metabolic model of L. lactis (pcLactis) to interpret growth on multiple nutrients. Through integration of proteomics and flux data, in glucose-limited chemostats, the model predicted glucose and arginine uptake as dominant constraints at low growth rates. Indeed, glucose and arginine catabolism were found upregulated in evolved mutants. At high growth rates, pcLactis correctly predicted the observed shutdown of arginine catabolism because limited proteome availability favored lactate for ATP production. Thus, our model-based analysis is able to identify and explain the proteome constraints that limit growth rate in nutrient-rich environments and thus form targets of fitness improvement.
KW - ccpA
KW - Laboratory evolution
KW - Lactococcus lactis
KW - Metabolic modeling
KW - Proteome constraint
U2 - 10.15252/msb.202010093
DO - 10.15252/msb.202010093
M3 - Journal article
C2 - 33821549
SN - 1744-4292
VL - 17
JO - Molecular Systems Biology
JF - Molecular Systems Biology
IS - 4
M1 - e10093
ER -